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COMPARISION OF THE MACHINING CHARACTERISTICS ON
ELECTRICAL DISCHARGE MACHINING BETWEEN TUNGSTEN
CARBIDE AND AISI H13
Shruti saxena
Email id.. shruti11mec@gmail.com
ABSTRACT
Electrical Discharge Machining is a process for shaping hard metals and forming deep and
complex shaped holes by arc erosion in all kind of electro-conductive materials. The objective of
this research is to study the influence of operating parameters of EDM of tungsten carbide and
AISI H13 on the machining characteristics. The effectiveness of the EDM process with tungsten
carbide and AISI H13 is evaluated in terms of the Material removal rate, the relative wear ratio
and the surface finish quality of the work piece produced. High material removal rate, low
relative wear ratio and good surface finish are conflicting goals, which cannot be achieved
simultaneously with a particular combination of control setting. The higher discharge current,
the faster is the machining time. Material removal rate and surface roughness of the workpiece
are directly proportional to the discharge current intensity. This study confirms that there an
optimum condition of precision machining of tungsten carbide and AISI H13 although the
condition may vary with composition of the materials, the accuracy of the machine and other
external factors.
INTRODUCTION
Electrical discharge machining utilizes rapid, repetitive spark discharges from a pulsating direct-
current power supply between the workpiece and the tool submerged into a dielectric liquid [1].
There is no physical cutting force between the tool and workpiece.EDM has prove especially
valuable in the machining of the super tough ,electrically conducting materials such as the new
space-age alloys. It is being used extensively in the plastic industry to produce cavities of almost
any shape in metal moulds. Although the application of EDM is limited to the electrically
conductive workpiece materials, the process has capability of cutting of these material regardless
of their hardness and toughness. during the EDM process, the main machining output parameters
are the material removal rate (MRR), tool wear ratio (TWR) and surface roughness (Ra) of the
workpiece. It is desirable to obtain the maximum MRR with minimum TWR and surface
roughness for AISI H13 [5] and the machining characteristics are the material removal rate,
relative wear ratio and surface roughness for tungsten carbide so, the conclusion from the study
may drive is, For all electrode materials, the material removal rate increases with increasing peak
current. At the low range of peak current, the relative wear ratio decrease with the peak current
for copper electrodes.
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EXPERIMENTAL SET-UP AND PROCEDURE
The workpiece material used in this study was AISI H13 tool steel. Prior to EDM processing, the
workpiece was cut in a cylindrical shape with a length of 20 mm and a diameter of 20 mm. The
main mechanical and physical properties of such workpiece material at different temperatures are
given in Table 1.
Table 1 Mechanical and physical properties of AISI H13
Temperature
[°C]
Density
[kg/dm3]
Specific heat
[J/(kg·K)]
Electrical
resistivity
[Ω·mm2/m]
Modulus of
elasticity
[N/mm2]
Thermal
conductivity
[W/m·K]
20°C 7.80 460 0.52 215×103 24.30
500°C 7.64 550 0.86 176×103 27.70
600°C 7.60 590 0.96 165×103 27.50
A series of experiment on EDM of tungsten carbide was conducted on a Roboform 40 electrical
discharge machine to examine the effects of input machining parameters such as the gap voltage,
peak current,and workpiece surface roughness. In the tests, the machining characteristics, i.e., the
output variables, namely Material removal rate, relative wear ratio and surface roughness. The
workpiece material properties of tungsten carbide is shown in Table 2.
Table 2 Workpiece material properties of Tungsten Carbide
Density Hardness Melting
point
Tensile strength Compressive
strength
toughness
15.1 g/cm3 HRA 87 2597°c 179 kg/mm2 410 kg/mm2 50kg/mm2
The tool material was forged commercial pure copper with the main properties given in Table 3.
The experiments were performed on a diesinking EDM machine (CHARMILLES
ROBOFORM200) which operates with an iso-pulse generator.
Table 3 Physical properties of copper electrode
Physical
properties
Thermal
conductivity
[W/m·K]
Melting
point [°C]
Boiling
temperature
[°C]
Specific
heat
[cal/g·°C]
Specific
gravity at
20°C
[g/cm3]
Coefficient
of thermal
expansion
[×10-6
(1/°C)]
Copper 380.7 1083 2595 0.094 8.9 17
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RESULTS AND DISCUSSION
Comparision of effect of peak current on tungsten carbide and AISI H13
The effect of peak current on material removal rate is shown in Fig. 1a for pulse duration 12.8,
25, 50, 100 and 200μs. At all values of pulse duration, the material removal rate increases with
the intensity of discharge current up to 48A and then decreases when machining with higher
current.
The effect of discharge current on the relative wear ratio is shown in Fig. 1b. In the testing range
from 16 to 64A, the relative wear ratio decreased slightly with discharge current up to about
24A, and then started to increase at a more gradual rate. The optimum peak current on the basis
of the relative wear ratio for tungsten carbide took place at about 24A, and with this current
setting the relative wear ratio is minimum at all setting of pulse-on time.
The effect of peak current on surface roughness is shown in Fig. 1c. The surface
roughness of tungsten carbide workpiece resulting from EDM increases with the discharge
current and ranges from Ra = 1.9μm at 16A to Ra = 3.7μm, at 64A. It is shown that the lower the
current, the finer will be the surface texture. The machining rate is proportional to the current
intensity. However, high amperage generally requires large machining areas, and produces
greater surface roughness.
Fig 1a Effect of peak current on material removal rate on tungsten carbide
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Fine finish is possible only at low amperage, but creates greater electrode wear. Thus, the finer
the required surface, the lower is the machining rate and the greater is the electrode wear.
Material removal rate increases as the energy input increases. The total energy depends on the
number of sparks each second and the amount of energy in each spark. The amount of material
removal is normally proportional to the energy used.
Fig 1b Effect of peak current on relative wear ratio on tungsten carbide
Fig 1c Effect of peak current on workpiece surface roughness on tungsten carbide
International Journal of Scientific & Engineering Research, Volume 6, Issue 5, May-2015 ISSN 2229-5518
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The correlation between machining characteristics and peak current in machining of AISI H13
tool steel using copper electrode are shown in Figs. 2a to 2b. According to these figures, an
increase in the peak current causes an increase in the MRR and Ra, but a decrease in the TWR.
By the increase in peak current, the discharge energy of the plasma channel and the period of
transferring of this energy into the electrodes increase. This phenomenon leads to a formation of
a bigger molten material crater on the workpiece which results in a higher surface roughness.
However, the dimension of plasma channel and the effect of thermal conductivity of electrodes
in dispersing the thermal from the spark collision position increase by the increase in pulse on
time. Consequently, by dispersing more heat from the spark stricken position and increasing the
amount of heat transferred from the plasma channel to the electrodes, the plasma channel
efficiency in removing molten material from the molten crater at the end of each pulse decreases,
while the dimensions of the molten crater on the electrodes increases. This effect is more
pronounced for copper electrode, since its thermal conductivity is much higher than that of the
workpiece. As a result, tool wear ratio decreases by increase in pulse on-time. The increase in
pulse on-time leads to an increase in the material removal rate, surface roughness, as well the
white layer thickness and depth of heat affected zone.
Peak current (μs)
Fig 2a. Effect of peak current on Material removal rate on AISI H13
MR
R
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Peak current (μs)
Fig 2b. Effect of peak current on relative wear ratio on AISI H13
Peak current (μs)
Fig 2c. Effect of peak current on surface roughness on AISI H13
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As, we compare the effect of peak current on electrical discharge machined between tungsten
carbide and AISI H13, the result is that the MRR of AISI H13 is more than the MRR of tungsten
carbide.Similarly by showing the graph of Relative wear ratio ,the RWR of tungsten carbide is
less than the AISI H13 and the surface roughness Ra of tungsten carbide is less than the AISI
H13.So by comparision of all these the tungsten carbide is better worpiece than AISI H13.
CONCLUSIONS An extensive experiment study has been conducted to investigate the effect of the machining
characteristics in edm of tungsten carbide and AISI H13. For the tungsten carbide, effect of the
peak current, it is observed that for all values of pulse duration, the material removal rate
increases with the increase of the peak current in the range of low current settings, and becomes
constant when machining at higher values of peak current. the relative wear ratio first decreases
slightly with the peak current and then increases with further increase of the peak current. there
is an optimum peak current, at which the relative wear ratio is minimum for all settings of pulse
duration. The surface roughness of the workpiece increases steadily with increasing peak current.
For the AISI H13 effect of the peak current, it is observed thal for all values of pulse
duration, the material removal rate increases with the increase of the peak current and increases
continsually. The relative wear ratio increases with increase of the peak current.The surface
roughness of the workpiece increases steadily with increasing peak current. By these study the
overall performance of tungsten carbide is more useful or better than the AISI H13workpiece.
REFERENCES
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Singapore. Journal of Materials Processing Technology 115 (2001) 344-358.
[2] U.P Singh, P.P Miller, W. Urquhart, The Influence of Electrical Discharge Machining
Parameters on Machining Characteristics, in ; Proceedings of the 25th International Machine
Tool Design and Research Conference, 1985. Pp. 337-345
[3] T.T. Chin, T.S Leong, optimization of EDM Machining Condition, Academics exercise,
National University of Singapore. Ingapore,1983.
[4] W.S Lau, M. Wang, W.B. Lee, Electrical Discharge Machining of Carbon Fibre
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[5] Mirsadegh Seyedzavvar , 2Department of Mechanical Engineering, Middle East Technical
University, Turkey Influence of Input Parameters on the Characteristics of the EDM Process ,
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[6] Abu Zeid, O.A. (1997). On the effect of electro-discharge machining parameters on
thefatigue life of AISI D6 tool steel. Journal of Materials Processing Technology, vol. 68, p. 27-
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[7] Abdullah, A., Shabgard, M.R. (2008). Effect of ultrasonic vibration of tool on electrical
discharge machining of cemented tungsten carbide (WC-Co). International Journal of Advanced
Manufacturing Technology, vol. 38, p. 1137-1147.
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